Abstract: A chemical mechanical polishing pad is provided having a polishing layer; and a window incorporated into the polishing layer; wherein the polishing layer comprises a reaction product of ingredients, including: a polishing layer prepolymer and a polishing layer curative system; wherein the polishing layer curative system includes a polishing layer amine initiated polyol curative, a polishing layer high molecular weight polyol curative and a polishing layer difunctional curative; and, wherein the window comprises a reaction product of ingredients, including: a window prepolymer and a window curative system; wherein the window curative system includes a window difunctional curative, a window amine initiated polyol curative and a window high molecular weight polyol curative; and, wherein the polishing layer exhibits a density of ?0.6 g/cm3; a Shore D hardness of 5 to 40; an elongation to break of 100 to 450%; and, a cut rate of 25 to 150 ?m/hr.

Abstract: A method of manufacturing grooved polishing layers for use in chemical mechanical polishing pads is provided, wherein the formation of defects in the polishing layers are minimized.

Abstract: A low defect chemical mechanical polishing composition for polishing silicon oxide containing substrates is provided comprising, as initial components: water, a colloidal silica abrasive; and, an additive according to formula I.

Abstract: A method of manufacturing polishing layers having a window for use in chemical mechanical polishing pads is provided, wherein a plurality of polishing layers having an integral window are derived from a cake, wherein the formation of density defects in the cake and the surface roughness of the polishing layers formed are minimized.

Abstract: A method for polishing a silicon wafer is provided, comprising: providing a silicon wafer; providing a polishing pad having a polishing layer which is the reaction product of raw material ingredients, including: a polyfunctional isocyanate; and, a curative package; wherein the curative package contains an amine initiated polyol curative and a high molecular weight polyol curative; wherein the polishing layer exhibits a density of greater than 0.4 g/cm3; a Shore D hardness of 5 to 40; an elongation to break of 100 to 450%; and, a cut rate of 25 to 150 ?m/hr; and, wherein the polishing layer has a polishing surface adapted for polishing the silicon wafer; and, creating dynamic contact between the polishing surface and the silicon wafer.

Abstract: The invention provides a plurality of polymeric particles embedded with alkaline-earth metal oxide. The gas-filled polymeric microelements have a shell and a density of 5 g/liter to 200 g/liter. The shell has an outer surface and a diameter of 5 ?m to 200 ?m with the outer surface of the shell of the gas-filled polymeric particles having alkaline-earth metal oxide-containing particles embedded in the polymer. The alkaline-earth metal oxide-containing particles have an average particle size of 0.01 to 3 ?m distributed within each of the polymeric microelements to coat less than 50 percent of the outer surface of the polymeric microelements.

Abstract: The invention involves a method of preparing an alkaline-earth metal oxide-containing polishing pad useful for polishing at least one of semiconductor, magnetic and optical substrates. The method includes introducing a feed stream of gas-filled polymeric microelements into a gas jet, the polymeric microelements having varied density, varied wall thickness and varied particle size. The method passes the polymeric microelements in the gas jet adjacent a Coanda block, the Coanda block having a curved wall for separating the polymeric microelements with Coanda effect, inertia and gas flow resistance. Then it separates various alkaline earth metal oxide constituents from the curved wall of the Coanda block to clean the polymeric microelements.

Abstract: A method for chemical mechanical polishing of a substrate comprising tungsten using a nonselective chemical mechanical polishing composition.

Abstract: A multilayer chemical mechanical polishing pad is provided, having: a polishing layer having a polishing surface, a counterbore opening, a polishing layer interfacial region parallel to the polishing surface; a porous subpad layer having a bottom surface and a porous subpad layer interfacial region parallel to the bottom surface; and, a broad spectrum, endpoint detection window block comprising a cyclic olefin addition polymer; wherein the window block exhibits a uniform chemical composition across its thickness; wherein the polishing layer interfacial region and the porous subpad layer interfacial region form a coextensive region; wherein the multilayer chemical mechanical polishing pad has a through opening that extends from the polishing surface to the bottom surface of the porous subpad layer; wherein the counterbore opening opens on the polishing surface, enlarges the through opening and forms a ledge; and, wherein the window block is disposed within the counterbore opening.

Abstract: A multilayer chemical mechanical polishing pad is provided, having: a polishing layer having a polishing surface, a counterbore opening, a polishing layer interfacial region parallel to the polishing surface; a porous subpad layer having a bottom surface and a porous subpad layer interfacial region parallel to the bottom surface; and, a broad spectrum, endpoint detection window block; wherein the polishing layer interfacial region and the porous subpad layer interfacial region form a coextensive region; wherein the multilayer chemical mechanical polishing pad has a through opening that extends from the polishing surface to the bottom surface of the porous subpad layer; wherein the counterbore opening opens on the polishing surface, enlarges the through opening and forms a ledge; and, wherein the broad spectrum, endpoint detection window block is disposed within the counterbore opening.

Abstract: A multilayer chemical mechanical polishing pad is provided, having: a polishing layer having a polishing surface, a counterbore opening, a polishing layer interfacial region parallel to the polishing surface; a porous subpad layer having a bottom surface and a porous subpad layer interfacial region parallel to the bottom surface; and, a broad spectrum, endpoint detection window block comprising, comprises an olefin copolymer; wherein the window block exhibits a uniform chemical composition across its thickness; wherein the polishing layer interfacial region and the porous subpad layer interfacial region form a coextensive region; wherein the multilayer chemical mechanical polishing pad has a through opening that extends from the polishing surface to the bottom surface of the porous subpad layer; wherein the counterbore opening opens on the polishing surface, enlarges the through opening and forms a ledge; and, wherein the window block is disposed within the counterbore opening.

Abstract: A stable, concentratable silicon wafer polishing composition for polishing silicon wafers is provided, containing: water; an abrasive; a cation according to formula (I); piperazine or a piperazine derivative according to formula (II); and, optionally, a pH adjusting agent; wherein the polishing composition exhibits a silicon removal rate of at least 300 nm/min. Also provided are methods of making and using the stabilized, concentratable chemical mechanical polishing composition.

Abstract: A chemical mechanical polishing composition for polishing silicon wafers is provided, containing: water; a cation according to formula (I); piperazine or a piperazine derivative according to formula (II); and, optionally, a pH adjusting agent; wherein the polishing composition exhibits a silicon removal rate of at least 300 nm/min. Also provided are methods of making and using the chemical mechanical polishing composition.

Abstract: A method for chemical mechanical polishing of a substrate comprising a germanium-antimony-tellurium chalcogenide phase change alloy (GST) using a chemical mechanical polishing composition comprising, as initial components: water; an abrasive; at least one of a phthalic acid, a phthalic anhydride, a phthalate compound and a phthalic acid derivative; a chelating agent; a poly(acrylic acid-co-maleic acid); and an oxidizing agent; wherein the chemical mechanical polishing composition facilitates a high GST removal rate with low defectivity.

Abstract: A method for chemical mechanical polishing of a substrate comprising a germanium-antimony-tellurium chalcogenide phase change alloy using a chemical mechanical polishing composition comprising water; 1 to 40 wt % colloidal silica abrasive particles having an average particle size of ?50 nm; and 0 to 5 wt % quarternary ammonium compound; wherein the chemical mechanical polishing composition is oxidizer free and chelating agent free; and, wherein the chemical mechanical polishing composition has a pH >6 to 12.

Abstract: A method of manufacturing polishing layers for use in chemical mechanical polishing pads is provided, wherein a plurality of polishing layers are derived from a cake, wherein the formation of density defects in the cake and the surface roughness of the polishing layers formed are minimized.

Abstract: The polishing pad is useful for polishing at least one of magnetic, optical and semiconductor substrates. The polishing pad includes a polishing layer having a polyurethane window. The polyurethane window has a cross-linked structure formed with an aliphatic or cycloaliphatic isocyanate and a polyol in a prepolymer mixture. The prepolymer mixture is reacted with a chain extender having OH or NH2 groups and having an OH or NH2 to unreacted NCO stoichiometry less than 95%. The polyurethane window has a time dependent strain less than or equal to 0.02% when measured with a constant axial tensile load of 1 kPa at a constant temperature of 60° C. at 140 minutes, a Shore D hardness of 45 to 90 and an optical double pass transmission of at least 15% at a wavelength of 400 nm for a sample thickness of 1.3 mm.

Abstract: The polishing pad is suitable for polishing patterned semiconductor substrates containing at least one of copper, dielectric, barrier and tungsten. The polishing pad includes a polymeric matrix; and the polymeric matrix being a polyurethane reaction product of a polyol blend, a polyamine or polyamine mixture and toluene diisocyanate. The polyol blend is a mixture of 15 to 77 weight percent total polypropylene glycol and polytetramethylene ether glycol; and the mixture of polypropylene glycol and polytetramethylene ether glycol having a weight ratio of the polypropylene glycol to the polytetramethylene ether glycol from a 20 to 1 ratio to a 1 to 20 ratio. The polyamine or polyamine mixture is 8 to 50 weight percent; and the toluene diisocyanate is 15 to 35 weight percent total monomer or partially reacted toluene diisocyanate monomer.

Abstract: A method of manufacturing grooved polishing layers for use in chemical mechanical polishing pads is provided, wherein the formation of defects in the polishing layers are minimized.

Abstract: A method for pretexturing a polishing surface of a chemical mechanical polishing layer is provided.